Title :
Compact Charge Model for Independent-Gate Asymmetric DGFET
Author :
Dessai, Gajanan ; Wu, Weimin ; Gildenblat, Gennady
Author_Institution :
Sch. of Electr., Comput. & Energy Eng., Arizona State Univ. (ASU), Tempe, AZ, USA
Abstract :
Analytical expressions for terminal charges of an independent-gate asymmetric double gate MOSFET (DGFET) are derived. The new charge model is C∞ continuous, valid for all bias conditions and does not involve charge-sheet approximation. This is accomplished by developing the symmetric linearization method in the form that does not require identical boundary conditions at the two Si-SiO2 interfaces and allows for the volume inversion in the DGFET channel. Verification of the model is performed with both numerical computations and 2D TCAD simulations under a wide range of biasing conditions. The terminal charges expressions are similar to those in the PSP bulk MOSFET model and in the PSP-based common-gate symmetric DGFET model. The latter becomes a special case of the new model.
Keywords :
MOSFET; numerical analysis; silicon compounds; 2D TCAD simulations; PSP bulk MOSFET model; Si-SiO2; compact charge model; independent-gate asymmetric DGFET; independent-gate asymmetric double gate MOSFET; numerical computations; symmetric linearization method; volume inversion; Approximation methods; Boundary conditions; Computational modeling; Doping; Equations; Fluctuations; Impurities; Logic gates; MOSFET circuits; Mathematical model; Numerical models; Poisson equations; Scalability; Scattering; Voltage control; Charge model; compact model; double-gate MOSFET; independent-gate asymmetric DGFET;
Journal_Title :
Electron Devices, IEEE Transactions on
DOI :
10.1109/TED.2010.2054470
